Transcript 030607
Experiment 3: Purification of Fumarase • Three week experiment – Wraps up with formal lab report • Abstract/Intro/Results/Discussion would be difficult to write super early • Keep up with M & M • Think about/work on intro? – DAQs after week 1 – Week 3 “DAQs” in lab report • Protein Explorer exercise – Assignment tomorrow – Due date will be pushed back a couple of days (originally Friday, March 16th) • Grading – Exams tomorrow – Paper summaries • Not even close Why purify a protein? • Determine amino acid sequence (1° structure) • Determine 3-D structure (2°, 3°, 4°) • Function of protein away from cellular partners (in vitro) – Interactions with other molecules – Enzyme catalysis – Inhibitors (drugs?) Four ‘goals’ this week • Lyse yeast – Determine how much fumarase you start with • Set up Nickel column • Set up/become familiar with pump/fraction collector • Anion exchange ‘trial’ 1st step of protein purification Lysis Centrifugation Get rid of insoluble cellular components -cell wall/membrane -organelles Soluble proteins How are cells/tissues lysed? • Enzymatic/chemical – Degrade cell membrane – Detergents/lytic enzymes • Mechanical – eg. Sonication (high energy sound waves) Yeast are very tough: cell wall • Mechanical lysis: Bead mill – Yeast + Glass beads + “Blender” – Lysis buffer • Bit of detergent to weaken the cell (& stabilize protein) • Phosphate at ~ neutral pH, some salt • Protease inhibitors Purify/separate fumarase • Physical/chemical characteristics: make it ‘unique’ among cellular proteins • Here: we’ve altered the characteristics of fumarase – Genetic manipulation – Add a ligand binding site…affinity purification Purify/separate fumarase Genomic (native) gene for fumarase (DNA) Codes for fumarase (protein) Could be purified based on -size -pI/charge -etc. Purify/separate fumarase Manipulated gene +~18 additional nucleotides Codes for fumarase + ~6 additional amino acids at the C terminus H-H-H-H-H-H We’ve added a gene to this strain of yeast! Unique feature among proteins Problem of protein stability • “Proteolysis” – Lysis of peptide bonds • Typically catalyzed: proteases – KEEP PROTEIN COLD • Slow down proteolytic enzymes – Chemical protease inhibitors • Block enzyme action Problem of protein stability • Structural stability – Native-like buffers • Prevent drastic changes in pH, osmolarity • Detergents can stabilize protein structure – *Mild* eg. Igepal, Tween-20, etc. – Many detergents destabilize protein structure, eg. SDS – Temperature • • • • Room temp too warm? Centrifugation Generate lots of heat Bead milling Storage? *Fumarase: relatively high affinity for stationary phase *Other proteins: mobile phase *Weak fumarase’s affinity by competition INSOLUBLE “Bead” H2O COVALENT http://tinyurl.com/ysn9ya Company’s handbook (Qiagen) H2O • Fraction collector • Pump • Gradient maker Anion exchange trial • Start with three proteins – Affinity for stationary vs. mobile phases (partitioning) • Change stationary phase/change partitioning – Watch volume used for gradient A: 25 mM Tris “Gradient maker” B: 25 mM Tris, 500 mM NaCl Equal volumes B A To column Start: 100% A Volumes decreased but still equal B 50%A 50%B B >100%B To column Halfway through: 50% A Column sees 0 mM NaCl Column sees 250 mM NaCl To column Close to the end: almost 100% B Column sees ~500 mM NaCl